Since LayoutPrespecialization has been enabled by default in all compiler
invocations for quite some time, it doesn't make sense for it to be treated as
experimental feature. Make it a baseline feature and remove all the
checks for it from the compiler.
Centralize the logic for figuring out the conformances for the various
init_existential* instructions in a SILIsolationInfo static method, and
always go through that when handling "assign" semantics. This way, we
can use CONSTANT_TRANSLATION again for these instructions, or a simpler
decision process between Assign and LookThrough.
The actually undoes a small change made earlier when we stopped looking
through `init_existential_value` instructions. Now we do when there are
no isolated conformances.
Better match the style of SILIsolationInfo by moving the code for determining
SILIsolationInfo from conformances or dynamic casts to existentials into
static `getXYZ` methods on SILIsolationInfo.
Other than adding an assertion regarding disconnected regions, no
intended functionality change.
When we introduce isolation due to a (potential) isolated conformance,
keep track of the protocol to which the conformance could be
introduced. Use this information for two reasons:
1. Downgrade the error to a warning in Swift < 7, because we are newly
diagnosing these
2. Add a note indicating where the isolated conformance could be introduced.
Specifically in terms of printing, if NonisolatedNonsendingByDefault is enabled,
we print out things as nonisolated/task-isolated and @concurrent/@concurrent
task-isolated. If said feature is disabled, we print out things as
nonisolated(nonsending)/nonisolated(nonsending) task-isolated and
nonisolated/task-isolated. This ensures in the default case, diagnostics do not
change and we always print out things to match the expected meaning of
nonisolated depending on the mode.
I also updated the tests as appropriate/added some more tests/added to the
SendNonSendable education notes information about this.
I am doing this so that I can change how we emit the diagnostics just for
SendNonSendable depending on if NonisolatedNonsendingByDefault is enabled
without touching the rest of the compiler.
This does not actually change any of the actual output though.
We were effectively working around this previously at the SIL level. This caused
us not to obey the semantics of the actual evolution proposal. As an example of
this, in the following, x should not be considered main actor isolated:
```swift
nonisolated(nonsending) func useValue<T>(_ t: T) async {}
@MainActor func test() async {
let x = NS()
await useValue(x)
print(x)
}
```
we should just consider this to be a merge and since useValue does not have any
MainActor isolated parameters, x should not be main actor isolated and we should
not emit an error here.
I also fixed a separate issue where we were allowing for parameters of
nonisolated(nonsending) functions to be passed to @concurrent functions. We
cannot allow for this to happen since the nonisolated(nonsending) parameters
/could/ be actor isolated. Of course, we have lost that static information at
this point so we cannot allow for it. Given that we have the actual dynamic
actor isolation information, we could dynamically allow for the parameters to be
passed... but that is something that is speculative and is definitely outside of
the scope of this patch.
rdar://154139237
This results in wrong argument/return calling conventions.
First, the method call must be specialized. Only then the call can be de-virtualized.
Usually, it's done in this order anyway, because the `class_method` instruction is located before the `apply`.
But when inlining functions, the order (in the worklist) can be the other way round.
Fixes a compiler crash.
rdar://154631438
* add `cloneFunctionBody` without an `entryBlockArguments` argument
* remove the `swift::ClosureSpecializationCloner` from the bridging code and replace it with a more general `SpecializationCloner`
Originally this was a "private" utility for the ClosureSpecialization pass.
Now, make it a general utility which can be used for all kind of function specializations.
OSSA lifetime canonicalization can take a very long time in certain
cases in which there are large basic blocks. to mitigate this, add logic
to skip walking the liveness boundary for extending liveness to dead
ends when there aren't any dead ends in the function.
Updates `DeadEndBlocks` with a new `isEmpty` method and cache to
determine if there are any dead-end blocks in a given function.
LifetimeDependenceInsertion inserts mark_dependence on token result of a begin_apply
when it yields a lifetime dependent value. When such a begin_apply gets inlined,
the inliner can crash because of the remaining uses of the token result.
Fix this by inserting mark_dependence on parameter operands that are lifetime dependence sources
and deleting the mark_dependence on token results in the inliner.
Fixes rdar://151568816
We are going to need to add more flags to the various checked cast
instructions. Generalize the CastingIsolatedConformances bit in all of
these SIL instructions to an "options" struct that's easier to extend.
Precursor to rdar://152335805.
In this case, what is happening is that in SILGen, we insert implicit
DistributedActor.asLocalActor calls to convert a distributed actor to its local
any Actor typed form. The intention is that the actor parameter and result are
considered the same... but there is nothing at the SIL level to enforce that. In
this commit, I change ActorInstance (the utility that defines actor identity at
a value level) to look through such a call.
I implemented this by just recognizing the decl directly. We already do this in
parts of SILGen, so I don't really see a problem with doing this. It also
provides a nice benefit that we do not have to modify SILFunctionType to
represent this or put a @_semantic attribute on the getter.
NOTE: Generally, Sema prevents us from mixing together different actors. In this
case, Sema does not help us since this call is inserted implicitly by the
distributed actor implementation in SILGen. So this is not a problem in general.
rdar://152436817
Currently we delete dead drop_deinit instructions in InstructionDeleter.
For address results, we may end up with ownership errors after being promoted to value forms.
For value results, fixLifetimes mode of InstructionDeleter will insert an illegal destroy_value
rdar://151104993
It derives the address of the first element of a vector, i.e. a `Builtin.FixedArray`, from the address of the vector itself.
Addresses of other vector elements can then be derived with `index_addr`.
Instead of passing in the substituted type, we pass in the
InFlightSubstitution. This allows the substituted type to be
recovered if needed, but we can now skip computing it for
the common case of LookUpConformanceInSubstitutionMap.
In language 6 mode keypath instructions are created as existentials and the optimizer needs to look through the `open_existential_ref` instructions to recognize a keypath.
rdar://150173106
When the utility is used by the ConsumeOperatorCopyableValuesChecker,
the checker guarantees that the lifetime can end at the consumes, that
there are no uses after those consumes. In that circumstance, the
utility maintains liveness to those consumes and as far as possible
without introducing a copy everywhere else.
The lack of complete lifetimes has forced the utility to extend liveness
of values to dead-ends. That extension, however, is in tension with the
use that the checker is putting the utility to. If there is a dead-end
after a consume, liveness must not be maintained to that dead-end.
rdar://147586673
Need to canonicalize the replacement type. Otherwise it could be generic if it is a typealias inside a generic type, e.g.
```
struct S<T> {
typealias I = Int
}
```
Otherwise, we can be inconsistent with isolations returned by other parts of the
code. Previously we were just treating it always as self + nom decl, which is
clearly wrong if a type is not self (e.x.: if it is an isolated parameter).
rdar://135459885
